Abstract
The cornea, the anterior meniscus-shaped transparent and refractive structure of the eyeball, is the first mechanical barrier of the eye. Its functionality heavily relies on the health of its endothelium, its most posterior layer. The treatment of corneal endothelial cells (CECs) deficiency is allogeneic corneal graft using stored donor corneas. One of the main goals of eye banks is to maintain endothelial cell density (ECD) and endothelial barrier function, critical parameters influencing transplantation outcomes. Unlike in vivo, the stored cornea is not subjected to physiological mechanical stimuli, such as the hydrokinetic pressure of the aqueous humor and intraocular pressure (IOP). YAP (Yes-Associated Protein), a pivotal transcriptional coactivator, is recognized for its ability to sense diverse biomechanical cues and transduce them into specific biological signals, varying for each cell type and mechanical forces. The biomechanical cues that might regulate YAP in human corneal endothelium remain unidentified. Therefore, we investigated the expression and subcellular localization of YAP in the endothelium of corneas stored in organ culture (OC). Our findings demonstrated that CEC morphology, ECD and cell-cell interactions are distinctly and differentially associated with modifications in the expression, subcellular localization and phosphorylation of YAP. Notably, this phosphorylation occurs in the basal region of the primary cilium, which may play central cellular roles in sensing mechanical stimuli. The sustained recruitment of YAP in cellular junctions, nucleus, and cilium under long-term OC conditions strongly indicates its specific role in maintaining CEC homeostasis. Understanding these biophysical influences could aid in identifying molecules that promote homeostasis and enhance the functionality of CECs.